FRS 347320
FINAL REPORT FOR GRANT NAG5-3938
SUBMITTED TO: The National Aeronautics and Space Administration
Planetary Astronomy Program
TITLE: Beginning Research with the 1.8-meter Spacewatch Telescope
ORGANIZATION: The University of Arizona
Lunar and Planetary Laboratory
PERIOD OF GRANT:
PERIOD REPORTED ON:
PRINCIPAL INVESTIGATOR:
1996 Dec. 1 - 2000 Nov. 30
1996 Dec. I - 2001 Feb. 9
Tom Gehrels
Professor
Lunar and Planetary Laboratory
University of Arizona
Kuiper Space Sciences Building
1629 East University Boulevard
Tucson, AZ 85721-0092
Phone: 520/621-6970
FAX: 520/621-1940
Email: [email protected]
Date
2._o[
BUSINESS REPRESENTATIVE: Ms. Lynn A. Lane
Senior Business Manager
Lunar and Planetary Laboratory
University of Arizona
Kuiper Space Sciences Building
1629 East University Boulevard
Tucson, AZ 85721-0092Phone: 520/621-6966
FAX: 520/621-4933
Email: [email protected]
c:_w_nnsaknag53938.fnl
https://ntrs.nasa.gov/search.jsp?R=20010020245 2018-05-22T04:19:57+00:00Z
Participating Professionals (all at the Lunar and Planetary Laboratory):
Terrence H. Bressi (B. S., Astron. & Physics)
Anne S. Descour (M. S., Computer Science)
Tom Gehrels (Ph. D., Astronomy)
Robert Jedicke (Ph.D., Physics)
Jeffrey A. Larsen (Ph. D., Astronomy)
Robert S. McMiUan (Ph.D., Astronomy)
Joseph L. Montani (M. S., Astronomy)
Marcus L. Perry (B. A., Astronomy)
James V. Scotti (B. S., Astronomy)
Engineer
Senior Systems Programmer
Professor, observer, and PI
Principal Research Specialist
Principal Research Specialist and observerAssociate Research Scientist & observer
Senior Research Specialist and observer
(Chief) Staff Engineer
Senior Research Specialist and observer
PROJECT SUMMARY
The purpose of this grant was to bring the Spacewatch 1.8-m telescope to operational status for
research on asteroids and comets. This objective was achieved; first light with the telescope was
in May 2000 and since then several tests and demonstrations of the facility's capability to observe
Earth-approaching Asteroids (EAs) have been made, including the first observations to be
incorporated into a peer-reviewed publication. The Spacewatch 1.8-m telescope will be the
largest in the world dedicated full time to finding and doing astrometry of asteroids and comets.
It will be used to search for asteroids and comets anywhere from the space near Earth to regions
beyond the orbit of Neptune, and to do astrometry and lightcurves on the fainter of such objects
that are already known. Its comparatively large aperture will permit faster discovery of the very
small asteroids in Earthlike orbits, such as 1998 KY26, that are coveted for their accessibility as
material resources in space, as well as recovery of EAs on their return apparitions when they tend
to be more distant and fainter than they were at the times of their discoveries. It will also tend to
find EAs when they do not happen to be close to Earth. Discoveries made under those
circumstances allow the objects to be followed for longer intervals, providing better
determinations of their orbits during their discovery apparitions. In addition to its size, the 1.8-m
Spacewateh telescope will have the unique capability of long strip scanning in any direction, for
example along the ecliptic (the plane of the solar system), and along the line of variation of EAs
with uncertain orbits that are being targeted for recovery.
PURPOSE AND JUSTIFICATION
The purpose of the Spacewatch project is to explore the various populations of small objects
throughout the solar system. Statistics on all classes of small bodies are needed to infer their
physical and dynamical evolution. More Earth Approachers need to be found for spacecraft
missions and to assess the impact hazard. (We have adopted the term "Earth Approacher", EA,
to include all those asteroids, nuclei of extinct short period comets, and short period comets that
can approach close to Earth. The adjective "near" carries potential confusion, as we have found
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in communicatingwith themedia,thattheobjectsarealwaysnearEarth,following it like acloud.) Persistentandvoluminousaccumulationof astrometryof incidentallyobservedmainbeltasteroids(MBAs) is permittingtheMinor PlanetCenter(MPC)to determinetheorbitsof largenumbers(tensof thousands)of asteroids.Suchalargebodyof informationwill ultimately allowbetterresolutionof orbit classesandthedeterminationsof luminosityfunctionsof thevariousclasses.Cometandasteroidrecoveriesareessentialservicesto planetaryastronomy.Statisticsof objectsin theoutersolarsystem(Centaurs,scattered-diskobjects,andTrans-NeptunianObjects;TNOs)ultimatelywill tell partof thestoryof solarsystemevolution. Spacewatchledthedevelopmentof sky surveyingby electronicmeansandhasactedasaresponsibleinterfacetothemediaandgeneralpublicon thisdisciplineandon theissueof thehazardfrom impactsbyasteroidsandcomets.
BACKGROUND
CCD scanning was developed by Spacewatch in the early 1980s, with improvements still being
made. Spacewatch was the first astronomical group to use drift scanning with a CCD, first to use
CCDs to survey the sky for comets and asteroids, first to do astrometry on an asteroid with a
CCD (1984 JZ on 1984 Apr. 28; numbered (3325) after our observation), first to do targeted
astrometry of an EA with a CCD (1983 TB, now known as (3200) Phaethon, on 1984 Sep. 22),
first to discover an asteroid with a CCD (the Trojan (3801) Thrasymedes), first to discover an EA
with a CCD (1989 UP), first to discover an EA with software (1990 SS; now (11885)), first to
discover a comet with a CCD (1991 x; modem designation 125P/1991 R2), and first to discover
an asteroid known to be monolithic (I998 KY26). At the time of this writing, Spacewatch still
holds the records for discovering the smallest known asteroid (1993 KA2; H=29), the closest
known approach of any asteroid to the Earth (1994 XMI; 105,000 km), the object with the most
Earthlike orbit (1991 VG), the largest TNO other than Pluto (2000 WRy06 = minor planet
(20000)), and the asteroid most accessible to spacecraft (the rapid rotator 1998 KY26 ). As of
2001 Feb. 9, Spacewatch had discovered 232 EAs, 16 Centaurs or scattered-disk objects, 17
comets, 7 TNOs, and rediscovered one lost comet (P/Spitaler in 1993). Since 1984, Spacewatch
has also made a total of 4,255 astrometric observations of comets, recovered 61 comets, and has
reported 320,214 astrometric detections of asteroids, mostly in the main belt, including more than
42,161 for which provisional designations have been credited by the MPC to Spacewatch. A
total of 5,051 positions of EAs have been reported by Spacewatch since 1989.
TECHNIQUE
Moving objects are discovered by scanning the sky with a charge-coupled device (CCD)
electronic imaging detector on the 0.9-meter Spacewatch Telescope of the Steward Observatory,
University of Arizona, located on Kitt Peak mountain in the Tohono O'odham Nation. Now that
the 1.8-m telescope is complete, similar observations will be made with it also. The principles of
Spacewatch observing have been described by McMillan and Stoll (1982), Frecker et al. (1984),
Gehrels et al. (1986), McMillan et al. (1986), Gehrels (1991), Rabinowitz (1991), Perry and
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Frecker(1991),Scotti(I 994),andJedicke(I 996). EachSpacewatchscanconsistsof threepassesoveranareaof skyusingaCCDfiltered to aban@assof 0.5-1.0p,m(approximatelyV+R+I with aneffectivewavelengthon typical asteroidsof 0.7pan).Theeffectiveexposuretimefor eachpassis 143secondsmultipliedby thesecantof thedeclination.Theareacoveredbyeachscanis 32 arcminutesin declinationby about28 timeminutesin right ascension. The
image scale is 1.05 arcseconds per pixel. Three passes take about 1.5 hours to complete and
show motions of individual objects over a one hour time baseline. The limiting magnitude with
the 0.9-m telescope on slowly moving objects in good conditions is about 21.8. More than 2000
deg 2 are now being surveyed per year with the 0.9-m telescope, and this practice or a similar
procedure will be adopted with the 1.8-m telescope.
ACCOMPLISHMENTS
1.8-meter Telescope: The telescope is described by Perry et al. (1996), McMillan (1998),
McMillan et al. (1998), Perry et al. (1998), McMillan et al. (2000), and the Spacewatch web site
http.'//www, lpl.arizona.edu./spacewatch). The mechanical design of the telescope is optimized by
finite-element analysis to provide high resonant frequencies. The mount is an altitude-azimuth
type for compatibility with the mirror support cell contributed by the Multi-Mirror Telescope
Observatory. The telescope and mount were fabricated in the University Research
Instrumentation Center of the University of Arizona. Both axes are driven by DC servo motors
directly coupled to friction rollers. The azimuth and elevation motors as well as the CCD
instrument stage are under computer control with low-level software provided by the Galil
Motion Control Co. and high-level software written by our Engineer Terry Bressi.
Optics: The optical configuration is f/2.7 folded prime focus with a flat secondary thatiocates
the focal plane in the center of the optical trusswork near the altitude axis. This shortened the
telescope enough to make the dome building affordable, and the fiat secondary preserves the fast
f/number of the primary mirror. The coma corrector designed by R. A. Buchroeder is a modified
Klee design of 5 spherical lens elements plus a Schott OG-515 filter transmitting longward of the
B bandpass. The filter greatly simplified lens design and reduces sky background while not
significantly reducing the brightness of asteroids. The distortion-free, flat, unvignetted field of
view is 0.8 deg in diameter and the image scale is 1.0 arcsec/24 micron pixel.
Detector: An SI424-AB 1-1 thinned, back-illuminated, antireflection-coated 2Kx2K CCD of
excellent cosmetic quality was obtained from Scientific Imaging Technologies, Inc. of Beaverton,
OR. This detector fills the available field of view of the 1.8-m telescope, and according to the
vendor's quality control sheet it is cosmetically almost perfect, being devoid of column or row
defects. The cryostat and electronic controller and readout system are being tested in our lab.
Cooling is by closed-cycle gas circulation, eliminating handling of liquid nitrogen. This system
will be able to drift scan up to twice the sidereal rate, as well as scan at subsidereal rates for more
sensitivity. A 5-second readout from four quadrants simultaneously also permits efficient
operation in "stop-and-stare" mode.
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ImageAnalysis Software: Thesoftwareto beusedatthe 1.8-mtelescopewill beamodifiedversion of that whichhasbeenin useat the0.9-mtelescope.LarsenandDescourdevelopedIMPACT: ImageMotion Packagefor Asteroids,Comets,andTransneptunians(Larsenet al.
2001 in preparation). IMPACT has an advantage over the peak-pixel detection algorithm in the
1990-vintage MODP software in that it requires that several pixels above threshold be spatially
correlated in order to qualify as a detected image. As a result, IMPACT can find fainter objects.
Since 1999 Sept. 29 it has been in use at the 0.9-m telescope. It finds 40% more asteroids per
scan, brings the efficiency for V<20 to above 90%, affords 0.2 mag more sensitivity, and can
detect smaller angular displacements than MODP. At the 1.8-m telescope, it will be used in a
greater variety of modes, including scanning at subsidereal and supersidereal rates and long
"staring" (sidereally tracked) exposures. Staring mode observations have already been made with
this software at the 0.9-m telescope.
Limiting V mag with the 1.8-m telescope will be 22.5 while scanning at the sidereal rate. In that
mode the rate of coverage of sky will be 2000 deg 2 per year. Fainter magnitudes can be reached
in longer "staring" exposures, while area coverage can be double that with fast scanning.
First Light Observations:
2000 May 3 - 1.8-meter First Light was focused starlight on a ground glass slide.
2000 June 15 - Stars were acquired with a video camera. The pole star (Polaris) was found and
positively identified. About six other stars were acquired, moving progressively further away
from the pole until the objects couldn't be found.
2000 September 14 - First asteroid light on 1.8-meter: A Panasonic low-light video camera was
used to capture images of the very fast moving object (VFMO), 2000 RD53. Integration time was
approximately 0.5 seconds per frame, thus there were very few stars in the field.
2000 September 15 - First digital data with 1.8-meter: The rotation stage is working, plus focus,
tip & tilt. We videotaped the focusing on a cluster, and then replaced the video camera with an
SBIG ST-6 cooled digital CCD camera. We got some star fields and saved the images.
2000 September 19 - First digital data on an asteroid with 1.8-meter: With the cooled digital
ST-6 CCD camera at prime focus, we determined the zero point of the instrument rotator
parallactic angle and acquired every object we pointed at without searching. We observed some
Landolt photometric standards as well. The high point of the night was our acquisition of the
very fast moving NEO 2000 RD53. We recorded several images showing its trail, thereby
simultaneously achieving for the 1.8-meter telescope the first digital data on an asteroid, the first
observation of an NEO, the first observation of a "Very fast moving object" (VFMO), and the
first observation of a potentially hazardous asteroid (PHA).
2000 September 20 - First data with potentially scientific value: We made a two hour series of
photometricmeasurementsof theVFMO 2000RD53.
2000September28 - Anotherlightcurve: Wemadethemostinterestingobservationswith the1.8-mtelescopeyet.Thedrivesoftwareis nowcapableof trackingona fastmovingasteroid(2000SM_0), andwe gotmorethan3hoursof measurementsof its apparentmagnitude.Thesedatawill be incorporatedintoapeer-reviewedpublication(Pravecet al. 2001, in preparation).
2000 Nov. 22 - Collimation: We got some images on the small ST-6 CCD (4 x 6 arcmin) thru
beautifully clear sky and excellent seeing (as reported by Montani on the 0.9-m telescope). The
purpose of these observations was to examine the image quality at the uncorrected prime focus
after the LPL Shop's collimation of the primary and secondary mirrors to plumbed laser beams,
and before the coma corrector was installed.
The images across the ST-6 field are uniform, round, and focusable down to 2 arcsec FWHM or
better. There is no evidence of coma in the realtime displays, which indicates the optical axis is
very close to the center of the CCD, unlike the September images. We also took a 5 rain
exposure with the rotation stage not rotating, to see where the arcs traced out by the stars are
centered. The image rotation axis seems to be not far beyond one comer of the CCD.
2000 Dec. 14 - Prime focus collimated: Mostly clear, and Tubbiolo reported 3 arcsec seeing at
the 0.9-m. We acquired focus near the middle of the range and the images look great - at least as
good as before Thanksgiving. So the secondary mirror is now where it needs to be, and the
primary and secondary are well collimated.
2001 Jan. 24 - We did the first successful test of the whole optical system of the 1.8-m telescope,
including the 6-element coma corrector lens system. Previous observations with this telescope
were made at prime focus, without the lenses that are needed to correct for the coma that is a
property of any parabolic primary mirror. The coma corrector is designed to give good images
over the full 0.8 degree wide field of view. To evaluate the images over this wide a field using
the small SBIG ST-6 CCD, we located the detector at 5 positions: on axis, and 4 positions
corresponding to the comers of our bigger science detector that we plan to install soon. The
images we took of the open cluster g Persei are seeing-limited both on and off axis, showing that
the optical design as well as the lens fabrication and the collimation of the whole system havebeen successful.
Construction of the Spacewatch Telescope was funded by grants from the Department of Defense
Clementine Program, NASA, the University of Arizona Foundation, and other private and
corporate donors. The dome and building was funded by the David and Lucile Packard
Foundation, the University of Arizona Foundation, and John and Ilene Nitardy of Seattle, WA,
and was dedicated as the David and Lucile Packard Building.
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Building and Dome:
The building was not funded by NASA, but NASA provided funds for salaries of Spacewatch
personnel who guided the design and supervised the construction. The building is completely
outfitted with pier, dome, electrical wiring, plumbing, telephone, fiber optic ethemet hookups,
and lightning protection. The building structural frame is made of steel and the walls are
Galvalum®, an aluminum-coated sheet steel product. The dome is also made of Galvalum®. In
addition to being maintenance-free, Galvalum® also has a high reflectivity, a low thermal inertia,
and a low thermal emissivity. This means it will not heat up much in the daytime and will not
chill down below the temperature of the ambient air at night. These are important properties for
an observatory. The building is elevated well above grade to minimize the cost of site
preparation, to minimize the effects of convective cooling of the ground on observing, and to
prevent the heat buildup that might occur in an enclosed ground floor, the cooling of which
would disturb the nighttime seeing.
The southwest wall of the building is flared out to admit air flow. Two powerful fans in the
opposite (northeast) wall are used to draw outside air into the building through the openings,
and/or through the open dome slit during observing. This is to prevent heat buildup in the
building with its attendant convective cooling that would interfere with the imaging by the
telescope.
The building has about 1105 square feet of usable floor space on a main floor plus a mezzanine
deck. A control room in the north comer is about 282 square feet in size and is ventilated by a
ducted blower to prevent heat from the computers and monitors from elevating the temperature.
Windows are provided to aid illumination of engineering work in the daytime. The windows
cannot be opened and are equipped with blackout shades so when the lights need to be turned on
at night to work on equipment, they do not interfere with the work of the other telescopes on KittPeak.
The dome has a full 360 ° set of electrified rails so the dome shutter can be opened or closed at
any azimuth position of the dome, and to provide lights on the inside surface of the dome. The
shutter opening is 90 inches across to permit easy centering of the 72-inch diameter telescope
aperture and to admit plenty of outside air to equilibrate the temperature around the telescope.
For protection against lightning, the building is equipped with static electricity dissipation rods
grounded through heavy gauge copper braid wire to copper plates buried under the concrete
footings of the building uprights. A Transtector_ electrical surge absorber prevents the
transmission into the building wiring of all but a direct hit by lightning. Fire protection is
provided by smoke detectors which cut all the electrical power to the building when smoke or
fire is detected, at which time battery-powered emergency lights come on. This system also has
an alarm audible outdoors and an automatic telephone dialer.
EDUCATION, PUBLIC OUTREACH, AND MEDIA CONTACT
These contributions by Spacewatchers are made without any compensation over and above their
regular University salaries.
Gehrels teaches "Universe and Humanity, Origin and Future," every spring semester for
undergraduate students at the University of Arizona and is developing a textbook for that. He
also continues with other duties such as the Dean's P&T Committee, the Graduate Certification
Committee and as a Marshall at all Commencements. Decades of service on the Van Biesbroeck
Committee came to an end in July 1997 when the Award was handed over to the American
Astronomical Society. At the University of Arizona Press, Gehrels was the founder and General
Editor of the Space Science Series, which resulted in 30 volumes, until Rick Binzel took over in
the Fall of 2000 with the preparation of"Asteroids III" and "Comets II." Gehrels was the
Principal Investigator of Spacewatch until he handed that over to McMillan on June 7, 1997,
after which he has been continuing as an observer.
In India, Gehrels continues as a Sarabhai Professor for consulting and lecturing such as in a UN
Course for graduate students from Bolivia, India, Indonesia, Kazakhstan, Kyrgizstan, Mongolia,
Nepal, North Korea, Sri Lanka, and Uzbekistan. His base is at the Physical Research Laboratory
in Ahmedabad; there are side trips to other institutions such as the Indian Institute of
Astrophysics in Bangalore. The interaction with the students and colleagues continues by e-mail
throughout the year. The paper of Bhandari and Gehrels (1999) resulted from this.
On the way to and from India there always are stops and engagements such as in 1997 for 6
lectures on comets and asteroids in 6 different places in Japan at the request of Dr. Isobe in
preparation for his NEO observatory. In July 1998 there was the meeting of the American
Geophysical Union in Taiwan, from which the statistics paper resulted (Gehrels 1999).
In this grant period, the publication of results from Pioneers 10 and 11 came to an end, and also
the Palomar-Leiden Surveys of asteroids and Trojans. The Spacewatch program is the CCD-based successor of the latter.
There were numerous interviews, some 15 television shows in this period alone, primarily on the
hazard aspect of the asteroids. Gehrels' theme of public lectures usually is "Origin and Evolutionof Comets and Asteroids."
Kitt Peak is in the Tohono O'odham Nation, where construction of buildings is normally subject
to the Tohono O'odham Employment Rights Ordinance (TERO) that ensures employment of
tribal members on construction projects. Although the UA, as part of the State of A_rizona, is
probably exempt from that ordinance, the Spacewatch Project voluntarily complied with it to
ensure that members of the tribe would participate in this expansion of the Project. The resulting
collaboration between the UA and the Tohono O'odham Nation includes continuing presentations
by Gehrels to hundreds of students of the three high schools of the Nation. A specific goal is to
eventuallyhavea Tohonoastronomeratthe 1.8-meter;Gehrelshasa 20-yearwagerrunning on
that with the Director of TERO. The way to reach this goal and win the wager is to get the
students enrolled in the Summer Camps directed by Astronomer Don McCarthy of the Steward
Observatory. (So far no luck, but we have 16 years left to succeed.)
Larsen invested considerable time training, coaching, employing, and tutoring students,
especially the seven who are working or did work for Spacewatch: Natasha Carpenter, Nichole
Danzl, Anne Descour, Arianna Gleason, Mike Read, Andrew Tubbiolo, and Ben Zuniga. Danzl
and Gleason have discovered EAs, Centaurs, and TNOs, while Descour did a magnificent job of
programming the IMPACT software interface. After obtaining her MS in Computer Science, she
was hired by us as a full time Senior Systems Programmer. Read and Tubbiolo's work with
computer hardware and electronics made it possible to modernize the data system at the
telescope, and they are both now also trained solo observers.
Larsen hosted numerous visits by colleagues and fans of Spacewatch to the telescope, most
notably to two groups from Raytheon Corp. and two groups of UA biologists. He gave a number
of interviews for radio, TV, and news magazines. These included The Arizona Daily Star's
science writer Jim Erickson and Sky & Telescope's Associate Editor Stuart Goldman on the topic
of the discovery of the 17th moon of Jupiter, Jens Ramskov, Ph.D., of lngenioren (Engineering
Weekly) of Denmark, Karelle Plummer, Jr. Exec. Producer of "Now Channel" in the UK, and
Sofia Loverdou of "Greek Newspaper" on the topic of Spacewatch's rediscovery of the lost
asteroid (719) Albert. Larsen was also interviewed by the University of Minnesota University
Relations about naming minor planet (10172) after Prof. Roberta Humphreys. That was carried
at least on the Tucson ABC-TV affiliate and published in The Tucson Citizen, The Minneapolis
Star, and The Minneapolis Tribune. In addition, Larsen gave an email interview about NEAs to a
freelancer, contributed to a press release by LPL's Agnieszka Przychodzen about Spacewatch
research on Centaurs and TNOs, and gave an interview to Jorge Ianiszewski from Circulo
Astronomico about Spacewatch's TNOs.
Larsen answered hundreds of questions from the general public received through access to our
web site and contributed a piece to Benny Peiser's "CCNet" listserve on the asteroid impact
hazard. Larsen's development of the Spacewatch web site
(http://www. Ipl.arizona. edu/spacewatch) was rewarded by awards from Key Resource,
StudyWeb, and Scout Report Selection services.
Larsen also gave two talks at the U. S. Naval Academy in Annapolis, Va. and a colloquium at the
Univ. of Minnesota. He is coaching a faculty member and midshipmen at the Naval Academy to
observe asteroids with their small but modern telescope. As a successful graduate of University
of Minnesota - Morris, Larsen was asked to reminisce about what their campus was like in the
"dark ages" of 1985-1989. (His response included the fact that he had to walk 10 miles uphill to
school each way in the snow.)
McMillan, Perry, Bressi, Scotti, and students Mastaler, Read and Tubbiolo, and Administrative
AssistantT. M. Laneof Spacewatchspentconsiderabletimecommunicatingwith andtraininganastronomerfrom theUlaanBaatarObservatoryin Mongolia. Thiseffort is fundedby agrantfrom AFOSR. Thepurposeof this educationis to developthecapabilityfor astronomersinMongolia to observeasteroids.This has been given a high priority by DoD/Pentagon.
McMillan gave video interviews for Phoenix commercial TV, UA News Services, the Tucson
affiliates of NBC-TV and PBS-TV, and the RSK program of Sanyo Broadcasting Co. of Japan.
He did an interview with reporter/still photographer Kazuya Nagase of Kyodo News of Japan.
He contributed to press releases and interacted extensively with the press on the topics of
Spacewatch's rediscovery of the long-lost asteroid (719) Albert and the Spacewatch discoveries
of S/1999 J1 (a satellite of Jupiter) and 2000 WRI06, the brightest known TNO other than Pluto.
McMillan and Montani hosted and assisted a still photography crew for Worth Magazine at the
Spacewatch telescopes. McMillan also gave tours of the Spacewatch telescopes for participants
of a Mars Conference, a meeting of chemists, an assemblage of UA Dept. Heads, an advisory
board to the UA College of Science, the Japan Spaceguard Association, and (with Gehrels and
Read) a United Kingdom Task Force on Near-Earth Objects. This latter helped that Task Force
write a thorough report to Her Majesty's Government on the hazard of impacts by asteroids that
was also well received internationally. McMillan's presentations at the Space Studies Institute in
Princeton, NJ and the Colorado School of Mines in Golden, CO reached students and members
of the general public in addition to professionals. With Mike Read he upgraded the Spacewatch
web page, and granted permission for many organizations, including planetaria, to use images
from the page for media productions. McMillan gave talks on Spacewatch to Prof. Steve Tegler's
physics class at Northern Arizona University in Flagstaff, to the Saddlebrooke retirement
community near Tucson, and a class of senior students at Tucson High Magnet School.
McMillan also provided technical advice to two science fiction writers.
Scotti gave several public lectures in this time period, including the Annual Dinner Meeting of
the Ottawa Centre of the Royal Astronomical Society of Canada in 1998 November, a guest
presentation and question and answer session at Vail Middle School in 1999 May, two phone
lecture and question and answer sessions with Edison High School (Fresno, CA), and a public
lecture in 2000 April at the Pima Air and Space Museum. Scotti's interaction with the press
extended from phone interviews and conversations, to film interviews, to live radio call-in
shows, magazine articles, and numerous web/e-mail related interactions, including several for
stories in newspapers or web publications. These were mostly for the (719) Albert story, but
there were also some on the impact hazard. He was interviewed on national TV in 1998 on the
1997 XFll affair, and wrote an article on his discovery of that closely-approaching asteroid for
Sky and Telescope magazine (Scotti 1998). Scotti did a radio interview on "Let's Talk Stars" on
KTKT with David Levy on Sept. 12, 2000, a radio interview on KXAM (Phoenix) with Dr. Sky
(Steve Cares) on Nov. 24, 2000, and a video interview for "Savage Planet". He was interviewed
by Jim Erickson of The Arizona Daily Star for the (719) Albert story.
10
REFERENCES
Frecker, J. E., T. Gehrels, R. S. McMillan, W. J. Merline, M. L. Perry, J. V. Scotti, and P. H. Smith 1984. ACCD system for photometry of direct and spectroscopic images. Proc. of the Wor_hop on Improvements toPhotometry, Eds. W. J. Borucki and A. Young, NASA CP-2350, 137-151.
Gehrels, T., B. G. Marsden, R. S. McMillan, and J. V. Scotti 1986. Astrometry with a scanning CCD. Astron.d. 91, 1242-1243.
Gehrels, T. 1991. Scanning with charge-coupled devices. Space Science Reviews 58, 347-375.Jedicke, R. 1996. Detection of near Earth asteroids based upon their rates of motion. Astron. J. 111,970-982.McMillan, R. S., T. Gehrels, J. V. Scotti and J. E Frecker 1986. Use of a scanning CCD to discriminate asteroid
images moving against a background of stars. In Instrumentation in Astronomy: Proc. S.P.I.E. 627 (D. L.Crawford, Ed.), V1141-154.
McMillan, R. S., and C. P. Stoll 1982. Software simulations of the detection of rapidly moving asteroids by acharge-coupled device. Proc. SPIE 331, Instrumentation in Astronomy IV, 104-112.
Perry, M. L., and J. E. Frecker 1991. The drive system of the Spacewatch CCD-scanning telescope. Bull. Amer.Astron. Soc. 23, 875.
Rabinowitz, D. L. 1991. Detection of Earth-approaching asteroids in near real time. Astron. d. 101, 1518-1529.Scotti, J. V. 1994. Computer aided near Earth object detection, in Asteroids, Comets, andMeteors 1993, A.
Milani etal., eds., Kluwer, 17-30.
SPACEWATCH PUBLICATIONS, 1996-2001
Spacewatch reported 194,556 astrometric detections (1 "detection" usually equals 3 "positions")
of asteroids and comets to the IAU's Minor Planet Center (MPC) in Cambridge, MA from 1996
December 1 through 2001 Feb. 3 inclusive. Half of these the MPC has already published in the
Minor Planet Circulars, with a resulting 26,506 object designations. A total of 1,942 positional
measurements (611 detections) were made of Earth-Approachers (EAs), 101 of which were new
Spacewatch discoveries reported in the Minor Planet Electronic Circulars (MPECs).
Spacewatch also discovered 12 Centaurs/Scattered-Disk Objects, 7 TNOs, 13 comets, and an
outer satellite of Jupiter (the smallest known) during this report period. Those discoveries were
all published as MPECs. We do not list all the MPECs here.
Bhandari, N., and T. Gehrels 1999. Faint comets and asteroids over geologic history and their
future hazards. Space Research in India: Accomplishments and Prospects (Ahmedabad, India:
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